The value of a river basin approach in climate adaptation1
Judy Oglethorpe2, Sunil Regmi3, Ryan Bartlett4, Bhawani S. Dongol2, Eric Wikramanayake2 and
Sarah Freeman4
Correspondence email: [email protected]
Abstract
Climate change is having major impacts on water resources, affecting the quantity, quality and
timing of water flows in many places. These changes are likely to increase as climate change
advances. Taking a holistic river basin approach to climate adaptation can bring many advantages
when building resilience in natural and human systems and addressing conflicts that will
increasingly arise as climate change advances. This paper reviews the advantages and challenges
of such an approach, drawing on results of a vulnerability assessment and adaptation planning for
the Gandaki river basin in Nepal using WWF’s ‘Flowing Forward’ methodology for assessing
vulnerability of different human and environmental systems. The paper reviews how the river
basin approach frames key adaptation issues and challenges, such as maintaining, provisioning,
and regulating ecosystem services; reconciling upstream and downstream needs for water and
ecosystem services by various sectors; and maintaining ecological connectivity in order to promote
adaptation of freshwater and terrestrial systems and species. Results can be applied in adaptation
planning at various levels, including for local communities. The paper also reviews interactions
between climate change and development, including changes in land use, hydropower
development and water extraction, and examines the value of environmental flow analysis to
understand likely combined impacts. Finally, it outlines the importance of multi-sectoral and
multi-scale adaptation approaches in river basins, including the need for appropriate institutional
structures and policy frameworks.
Key words: river basin, climate change, ecosystem services, hydropower, environmental flow
1 Presented at International Conference on Climate Change Innovation and Resilience for Sustainable Livelihoods,
Kathmandu, Nepal, 12-14 January 2015, and subsequently updated in 2016. 2 WWF Nepal, PO Box 7660, Baluwatar, Kathmandu, Nepal 3 CARE Nepal, PO Box 1661, Lalitpur, Nepal 4 WWF US, 1250 24th Street NW, Washington, DC 20037, USA
Introduction
Changes in climate have caused impacts on natural and human systems around the world in recent
decades (Intergovernmental Panel on Climate Change 2014): changing precipitation or melting
snow and ice are altering hydrological systems and affecting quality and quantity of water
resources; glaciers continue to shrink, affecting runoff and water resources downstream; species
range shifts, changing migration patterns, and population changes are manifesting across the
world; and crop yields are changing, resulting in more decreases than increases. Impacts from
climate-related extremes and associated hazards, such as heat waves, droughts, floods, cyclones
and wildfires, reveal significant vulnerability and exposure for both human systems and
ecosystems. Climate-related hazards exacerbate other stressors for ecosystems and for livelihoods,
especially among people living in poverty.
As climate change advances, its impacts will multiply and become more extreme, with greater
impacts on water, agriculture, forestry, energy, transport, settlements, conservation, and health
sectors. This paper outlines the value of using river basins as a unit of intervention for building
resilience to climate change and climate variability, and promoting adaptation. It draws on the
example of the Gandaki river basin in Nepal (Figure 1), where the Hariyo Ban Program5 used
‘Flowing Forward’ methodology to assess vulnerability of different human and environmental
systems (WWF Nepal 2016a). Designed for large drivers of change at the landscape scale in a
data-poor environment, this methodology assesses vulnerability of natural and man-made
landscape features through a synthesis of existing background information, peer-reviewed and
gray climate science literature, and a participatory stakeholder assessment workshop that includes
scenario planning for an uncertain future. The Gandaki assessment was enhanced by information
from local level vulnerability assessments and adaptation planning in selected parts of the basin.
The core principles behind integrated river basin management (IRBM) and integrated water
resources management (IWRM) at the heart of the Flowing Forward approach are not new; IWRM
is a process which promotes the coordinated development and management of water, land and
related resources, in order to maximize the resultant economic and social welfare in an equitable
manner without compromising the sustainability of vital ecosystems (Global Water Partnership
2000). In the face of climate change they have increased urgency and importance as a sound
approach for integrated climate adaptation.
The Gandaki basin in Nepal covers 32,057 square kilometers, and encompasses a varied
topography from the trans-Himalayan desert and the snowcapped high Himalaya mountains in the
north, down through the mid-hills to the Churia (Siwalik) range and the low-lying plains of the
Terai in the south. Elevation ranges from 8,091 m at the peak of Annapurna I, the tenth highest
mountain in the world, to around 200 meters above sea level in the Terai. A small part of the basin
lies in China to the north; the basin drains through the Narayani River in the south to India, where
it forms a tributary of the Ganges river. The basin has important water resources, with several
5 Hariyo Ban (Green Forests) Program is ten-year project funded by USAID that aims to reduce adverse impacts of
climate change and threats to biodiversity in Nepal. It is implemented by a consortium of WWF, CARE Nepal, the
Federation of Community Forests User Groups Nepal and the National Trust for Nature Conservation
major perennial rivers: Kali Gandaki, Seti, Marsyangdi, Daraundi, Budhi Gandaki, Trishuli, and
Rapti. The basin is inhabited by over 4.5 million people of diverse ethnicities. In rural areas people
are still heavily dependent upon forests and ecosystem services for their livelihoods and wellbeing;
the basin has about 35% forest cover (Ministry of Forests and Soil Conservation 2015). Migration
from high altitudes to lowlands, rural to urban areas, and to other countries in search of better
livelihood opportunities is common in the region; remittances from employment are the major
source of household income (46%). Agriculture, tourism, salaried jobs/services and wage labor are
the next largest income sources. Hydropower and other infrastructure are rapidly developing in the
basin (WWF Nepal 2013). The eastern part of the basin was seriously affected by the 2015
earthquake whose epicenter was in Barpak in Gorkha district.
Figure 1: The Gandaki river basin in Nepal, showing major rivers and bio-geographical zones
Advantages of taking a holistic river basin approach in light of climate change
Maintaining ecosystem services for people and nature: The most common and serious climate
hazards faced by local communities in the Gandaki basin, from over 200 community level
vulnerability assessments supported by the Hariyo Ban Program in the basin, are: storms including
hail; landslides, floods and droughts; uncontrolled forest fire; and spread of invasive species and
diseases (WWF Nepal 2016b). Impacts include declining agricultural production and rising food
insecurity; drying of water sources; and increased disaster risk. Vulnerability tends to be very site-
specific, especially given the huge range in altitudes and topography, but also due to socio-
economic factors including gender, poverty and social exclusion.
As people become more exposed to climate change hazards, ecosystem services can play important
roles to buffer their effects: for example, forests can reduce the risk of local flash floods and
landslides in the face of more intense localized rainfall and help to maintain dry season water
supplies as precipitation patterns become increasingly unpredictable. Functioning floodplains can
absorb floodwater and reduce the risk of floods downstream, while also providing critical nutrients
for flood dependent vegetation and agriculture (e.g. Secretariat of the Convention on Biological
Diversity 2009; Le Quesne 2010). Ecosystems can also act as a safety net for communities when
agriculture fails by providing wild foods and other resources, and a place to take temporary shelter
from disaster hazards. Hence, restoring or maintaining these ecosystem services can play a major
role in adaptation in the face of future uncertainty (e.g. Andrade et al. 2011). This needs to be done
holistically and in conjunction with other land uses such as agriculture and industry that often rely
on but can also affect the integrity of these services.
Therefore, working at site level is often not enough; interventions may need to be at spatial scales
at which ecosystem services operate. For example, bio-engineering to stabilize landslides and river
banks downstream may not be effective when land use problems such as increased runoff from
upstream deforestation are not tackled. On the other hand, adaptation activities by upstream
stakeholders may risk maladaptation if individual communities, countries and sectors take
adaptation measures unilaterally without considering possible consequences for ecosystems and
other users beyond their immediate jurisdiction: for example, building a dam to boost a town’s
dwindling water supply can cause wetlands and irrigation canals to dry up downstream.
Hence, building climate resilience often needs to take place at multiple levels and rely on
communication, coordination and decision-making among stakeholders. In the Gandaki basin, the
Hariyo Ban Program has worked with the Department of Soil Conservation and Watershed
Management to facilitate dialogue between upstream and downstream communities in sub-
watersheds in collaboration with local stakeholders through support to the implementation of
integrated subwatershed management plans, and is collaborating with Government to expand this
work to include larger sub-basins and the Gandaki basin itself, with a wider range of stakeholders.
River basins represent an ideal scale that accounts for ecosystem services since the ecological links
and dynamics that human activities affect or rely on are usually contained within the catchment
boundaries. As a result, they can be integrated into a river basin plan where trade-offs can be
analyzed by upstream and downstream stakeholders, and decisions made on the basis of holistic
understanding. Large basins such as the Gandaki contain many nested scales including sites, small
catchments, and sub-basins such as the Seti and Marsyangdi. In 2015 the Ministry of Forests and
Soil Conservation (MoFSC) recognized the Gandaki basin as a conservation landscape with the
goal of managing it through an integrated, river basin planning approach which is built on the
foundation of climate-smart conservation and sustainable development practices to promote
persistence of biodiversity, and sustainable management of natural resources for continued
provision of ecosystem goods and services that support equitable and inclusive socio-economic
prosperity (MoFSC 2015).
Natural systems are also coming under increasing stress from climate change, and it is important
to understand their vulnerabilities and integrate resilience building and adaptation measures for
species and ecosystems into planning processes, to maintain ecosystem services for as long as
possible, as well as for biodiversity conservation. Reducing non-climate stresses such as
overharvesting of forest resources or overgrazing can play a major role in increasing ecosystem
resilience (e.g. Hansen et al. 2003), though other climate change-focused interventions will also
be needed. For this, information is required on the specific factors that affect system resilience and
overall vulnerability. In the Gandaki river basin the natural systems that were found to be most
vulnerable include sub-tropical broadleaf forest and semi-desert coniferous forest; the Seti and
Rapti sub-basins; spring sources in the Churia and floodplains; and migratory birds and gharial (a
crocodile species). Vulnerable man-made systems were rainfed agriculture (pakho) in the mid-
hills; agriculture on leveled, irrigated land (tar) in the mid-hills and Siwaliks; and rural settlements
and local roads (Table 1) (WWF Nepal 2016a). Hariyo Ban Program and partners have been able
to start implementing several of the recommendations from the assessment (Table 2): for example,
through a major focus on the Seti sub-basin; promoting climate-smart agricultural practices;
promoting alternative energy and improved cook stoves to reduce pressure of firewood collection;
and climate-smart community forest management.
Table 1: Most vulnerable ecological and man-made systems in the Gandaki basin
Focus Area Most Vulnerable Systems and
Species Region
Forests Subtropical Broadleaf Siwalik/Churia Range
Semi-desert Coniferous Trans-Himalayan Region
Freshwater Spring Sources Siwalik/Churia Range
Floodplains Basin-wide
Species Migratory Birds Basin-wide
Gharial Siwalik/Churia Range
Agriculture Pakho Mid-hills
Irrigated Tar Mid-hills/Siwalik
Rivers Seti Sub-basin-wide
Rapti Sub-basin-wide
Infrastructure Rural Settlements Basin-wide
Local Roads Basin-wide
(WWF Nepal 2016a)
Table 2: Proposed Adaptation Interventions
Focus Area Proposed Interventions
Forests
Promote alternative energy sources and improved cook stove programs to reduce fuel wood demand and
deforestation/degradation
Promote “climate-smart” community based forest management, focusing on fire prevention and control, and
afforestation in denuded areas
Freshwater Enhance monitoring for freshwater systems, focusing on glacial extent and snow line, and snow-water equivalent in
higher altitudes; and water quality in lower lying areas of the Mid-hills and Siwaliks
Sub-catchments Install early warning systems in floodplain communities that regularly experience flooding, alongside climate change
sensitization and disaster preparedness programs
Species Identify and conserve important winter/nesting areas for altitudinal migrant birds, based on projected habitat changes
according to climate scenarios
Work with upstream watershed communities to reduce fertilizer and pesticide use and develop soil management
practices to reduce runoff and siltation.
Agriculture Increase funding for agriculture extension services, including for climate-smart farming techniques and overall
climate change awareness
Improved access to seasonal climate information for farmers, including suggested planting dates and weather
forecasts
Infrastructure Mandate climate vulnerability assessments for all proposed large infrastructure developments, including national
roads and hydropower dams
Eliminate unplanned road construction through incentives for “green roads” construction alternatives that have
proper drainage and gradation.
(WWF Nepal 2016a)
Maintaining connectivity and enabling species shifts: River basins span altitudinal gradients;
the Gandaki basin is an extreme example with an altitudinal range from a few hundred meters to
over 8000 m, with eight major vegetation zones from lowland Sal forest to subalpine scrub (Thapa
et al. 2016). As temperatures rise, many species will respond by shifting their range distributions,
usually upwards. This was modelled for selected tree species, to help develop guidance on species
for tree planting in light of climate change (WWF Nepal 2016c). For example, Figure 1 shows
projected distribution of sal (Shorea robusta) in 2050 using the IPCC A2A greenhouse-gas
emissions scenario (the highest IPCC GHG emission scenario; note the caution about using
modelling results below). Under this projection, sal is likely to disappear from many low-lying
areas in the Terai that are not refugia, and to shift further north along the river valleys to the north
of the Churia range and up the surrounding slopes. Given the east-west running ridges in much of
the basin, many of the tall south-facing slopes are likely to become pose barriers for northward
movement as they become hotter and drier with climate change; hence the river valleys that cut
through them are likely to be very important for facilitating climate-induced range shifts of many
plant and animal species. They are already used by birds and fish during traditional seasonal
migrations.
Figure 2: Projected distribution of sal (Shorea robusta) in 2050 using the IPCC A2A
greenhouse-gas emissions scenario.
(Caution: the A2A is the highest IPCC GHG emission scenario. Different results would be
obtained using other scenarios. To accommodate uncertainties of climate projections, this model
and analytical process should be considered and evaluated against other knowledge.)
(WWF Nepal 2016c)
Well planned and managed river basins can provide large blocks and corridors of intact habitat for
freshwater and terrestrial species to shift along, and promote adaptation of systems and species.
While it is too early to know how successful uphill movements of whole systems or vegetation
types will be given the complex ecological inter-dependencies, maintaining and enhancing
corridors between them improves the chances for successful adaptation. Special management for
areas that are natural climate refugia can help conserve species that may disappear from
surrounding areas (local-level refugia are likely to include north-facing slopes and steep river
valleys which are cooler and more humid than surrounding areas). The Gandaki basin-scale
vulnerability assessment used connectivity as one of its criteria for testing resilience of natural
systems (WWF Nepal 2016a); the Hariyo Ban Program is working to restore terrestrial
connectivity in priority areas such as the Seti sub-basin in places where it has been interrupted,
and to identify potential climate refugia for special management. Unfortunately, existing and
planned hydropower development on all the main rivers of the basin (WWF Nepal 2014) is
becoming a major impediment for freshwater connectivity and adaptation, a phenomenon that is
increasingly common in the Himalaya. Long-term monitoring plots are being established to
monitor the impacts of climate change on both terrestrial and freshwater biodiversity and the local
communities who depend on these natural systems, along the altitudinal range of the Gandaki
basin.
Enabling holistic, climate-smart planning for economic development: In Nepal’s river basins,
climate change impacts will be manifested in a matrix of different land uses, including new
development. Infrastructure development is essential for the country’s development, and includes
hydropower projects, transmission lines, large-scale irrigation, local and national roads, and
expanding settlements and industry. However, many (though not all) infrastructure developments
have weak environmental impact assessment and mitigation measures (WWF Nepal 2014). Many
roads and dams in particular are having or are likely to have major adverse environmental and
social impacts; and high demand for building materials, including for post 2015-earthquake
reconstruction, is increasing destructive mining of sand, gravel and stone in many rivers and fragile
forest areas. Large-scale development and reconstruction projects also attract labor, resulting in
out-migration from farms, which may in turn lead to increased erosion of fallow abandoned lands
(for example if terraces erode). Some of these are reverting to forest, but many are being overtaken
by invasive species.
These environmental costs of development are likely to be exacerbated by climate change. For
example, heavier rainfall is likely to intensify erosion and landslides from poorly designed and
constructed roads; thus, road design should take climate change into account, with ability to cope
with heavier storms and rising temperatures (WWF Nepal 2014). Hydropower plants, particularly
run-of-the-river types, are highly dependent on predictable runoff patterns. But changing
precipitation patterns make for unreliable flows, especially during the dry season, and also increase
the risk of flooding (e.g. from glacier lake outburst floods, landslides blocking rivers, and intense
localized rainfall), which could jeopardize the viability of these power plants. Increased sediment
loads due to more intense rainfall—which are already high in the Gandaki basin from natural
erosion, deforestation and poorly constructed roads and other infrastructure—will accelerate
mechanical damage to machinery, including turbines. The combination of multiple hydropower
developments on the same river, along with climate change effects, could have a major impact on
the success of hydropower generation.
Results of an environmental flows analysis6 being undertaken in the Kali Gandaki stem of the
Gandaki from Mustang to Chitwan will soon be available, which will improve understanding of
6 An environmental flow is the water regime provided within a river, wetland or coastal zone to maintain ecosystems and their
benefits where there are competing water uses and where flows are regulated. Environmental flows provide critical contributions
flow requirements for targets such as traditional agriculture, domestic water supplies, water-based
tourism, connectivity for aquatic organisms and fisheries, wetlands in Chitwan, and religious and
cultural practices along the river. It will enable scenario planning for different climate change and
development scenarios to project impacts on ecosystems and the critical services they provide for
people in the basin; and provide a tool to develop solutions through improved siting, design and
operation of hydropower, taking into account the combined effect of hydropower projects,
including storage dams. A large-scale integrated river basin management approach is essential to
increase the resilience of these projects, and to provide optimal outcomes for both people and
ecosystems.
Need for a multi-sectoral, multi-scale, participatory approach
As people and species strive to adapt to climate change, there will be increasing tension between
sectors, upstream and downstream human communities, and even countries over shared resources
and ecosystem processes. Using river basins as a planning unit provides a holistic approach that
can integrate adaptation planning across sectors around shared water and land resources:
agriculture, forestry, fisheries, water, energy, transport, settlement, conservation, and health. A
multi-disciplinary approach that facilitates horizontal coordination across sectors will be essential
to tackle the challenges ahead, building resilience and facilitating adaptation to hazards that
include less predictable precipitation, and increased risk of landslides, floods, drought, and
uncontrolled forest fire. Horizontal coordination and collaboration at local levels among
neighboring community groups is critical to enable them to manage shared resources such as
forests and water more effectively and tackle common hazards. It is especially important to identify
and take into account the needs of the most vulnerable people, who are often women, the poor and
marginalized groups. In the Gandaki basin the Hariyo Ban Program is working to empower and
educate these stakeholders about their rights and about climate change, so that they can take part
in vulnerability assessments and community-level adaptation planning, ensuring their needs are
adequately covered.
Climate adaptation cannot take place in a vacuum; it needs to be mainstreamed with official
planning processes at different levels. Nepal being a highly disaster prone country, disaster risk
reduction planning is already occurring in many districts but in a parallel process to climate
adaptation planning, through the preparation of local disaster risk management plans. Since there
is a large overlap between disaster risk reduction and climate adaptation, Hariyo Ban has been
working with the National Network of Community Disaster Management Committee and its
chapters to pilot the integration of climate adaptation and disaster risk reduction planning (CARE
2016 a). It has also collaborated with village development committees (the lowest level of
government) to mainstream adaptation and DRR into local government planning, in order to
institutionalize DRR and adaptation, bringing local stakeholders’ inputs as well as ecosystem
aspects, and leverage funds for implementation (CARE 2016 b).
Vertical integration is also essential, with two-way communication and collaboration among local,
district or sub-basin, river basin, national and transboundary levels. In planning processes it is
to river health, economic development and poverty alleviation. They ensure the continued availability of the many benefits that
healthy river and groundwater systems bring to society (Dyson et al. 2008).
important to ensure that the traditional water needs of downstream communities and ecosystems
are met even as far as possible, in light of future climate change scenarios as well as large-scale
infrastructure development. As the new federal structure is introduced in Nepal, following the
promulgation of the Constitution in 2015, planning processes need to be adapted for the new levels
of government and jurisdictional boundaries, and capacity needs to be built among new office-
bearers for this. Provincial boundaries dissect the basin; it is important to promote collaboration
among the provinces that will share the Gandaki basin (upstream/downstream, and left/right
banks). There are good opportunities for benefit sharing arrangements among the three new tiers
of government, for example from hydropower, and payments for ecosystem services mechanisms.
Importance of sound policy, planning, governance and institutions
To facilitate integration, climate adaptation should be mainstreamed into integrated river basin
plans, rather than treated as a separate activity. Plans should incorporate scenario planning given
future uncertainties, with built-in flexibility. Trade-off decisions are inevitable, for which multi-
disciplinary economic, social and environmental analyses, and participatory and equitable
decision-making will be needed. Successful river basin management requires an effective and
impartial coordinating institution with the authority and mandate to act, and is accountable to all
stakeholder groups (Cook et al. 2011). It also must be able to coordinate across political boundaries
when catchment boundaries transcend political boundaries. Coordinating institutions will need to
be much more flexible in the future to allocate water and natural resources in the face of increasing
climate variability, uncertainty and extreme events, and be willing to test innovative approaches,
learn and adapt. Finally, policies should be harmonized to avoid existing contradictions and
overlaps which could constrict the coordinating body’s ability to act and adapt.
Conclusion and way forward
As climate change advances, it is critical to proactively plan and prepare for change in an
innovative, integrated and flexible way to maintain ecosystem services, resolve competing needs,
ensure the rights of vulnerable groups, and avoid maladaptation. River basins provide a sensible
natural geography-bounded unit to assess and analyze the ecological dynamics, and to bring
stakeholders together at multiple scales to manage shared resources more effectively, ultimately
increasing the resilience of people, infrastructure and ecosystems. The Gandaki basin offers an
ideal opportunity to demonstrate these principles, but will require strong leadership, political
commitment and technical inputs to make it happen.
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Acknowledgements
We would like to acknowledge the assistance of all those who worked on studies and assessments
for the Hariyo Ban Program in the Gandaki Basin, and WWF Nepal’s GIS staff for the maps.
Disclaimer: This paper is made possible by the generous support of the American people through
the United States Agency for International Development (USAID). The content is the responsibility
of the authors and does not necessarily reflect the views of USAID or the United States
Government.